The paper describes a new theory of the formation and growth of water droplets in multistage steam turbines. The essence of the theory is that large-scale static temperature fluctuations caused by the segmentation of blade wakes by successive blade rows have a dominating influence on nucleation and droplet growth in turbines. ‘True’ turbulent fluctuations (due to shear-layer unsteadiness, etc.) are probably less important and are ignored. A Lagrangian frame of reference is adopted and attention is focused on a large number of individual fluid particles during their passage through the turbine. Homogeneous nucleation and growth of droplets in each fluid particle is assumed to be governed by classical theories. All fluid particles are assumed to experience the same pressure variation, but those particles passing close to the blade surfaces suffer greater entropy production and, therefore, have higher static temperatures than those that pursue nearly isentropic paths through the central portions of the blade passages. Particles which suffer high loss therefore nucleate later in the turbine than those that experience little dissipation. Condensation is thus viewed as an essentially random and unsteady phenomenon because the dissipation experienced by a fluid particle in one blade row is assumed to be uncorrelated with its previous history. On a time-averaged basis, the condensation zone is spread over a much greater distance in the flow direction than a simple steady-flow analysis would indicate and may encompass several blade rows, depending on the number of stages in the machine. Predicted droplet size spectra show broad, highly skewed distributions with large mean diameters and sometimes slight bimodality. These are all characteristics of experimentally measured spectra in real turbines. Conventional, steady-flow calculation methods, which predict a fixed Wilson point in a specific blade row and a nearly monodispersed droplet population, cannot reproduce any of these characteristics.
[2]
J. Denton.
Throughflow Calculations for Transonic Axial Flow Turbines
,
1978
.
[3]
Abhijit Guha,et al.
Time-marching prediction of unsteady condensation phenomena due to supercritical heat addition
,
1991
.
[4]
P. T. Walters.
27. Improving the accuracy of wetness measurements in generating turbines by using a new procedure for analysing optical transmission data
,
1989
.
[5]
C. J. Lawn,et al.
Principles of combustion engineering for boilers
,
1987
.
[6]
J. B. Young.
Semi-analytical techniques for investigating thermal non-equilibrium effects in wet steam turbines
,
1984
.
[7]
W. T. Lindsay,et al.
The Verification of Concentrated Impurities in Low-Pressure Steam Turbines
,
1983
.
[8]
P. T. Walters,et al.
21. A reconsideration of wetness loss in LP steam turbines
,
1989
.
[9]
Abhijit Guha,et al.
Normal shock-wave structure in two-phase vapour-droplet flows
,
1991,
Journal of Fluid Mechanics.
[10]
J. Young.
Spontaneous condensation of steam in supersonic nozzles
,
1982
.
[11]
J. Young,et al.
Two-Dimensional, Nonequilibrium, Wet-Steam Calculations for Nozzles and Turbine Cascades
,
1992
.
[12]
J. L. Kerrebrock,et al.
Intra-Stator Transport of Rotor Wakes and Its Effect on Compressor Performance
,
1970
.